• Corpus ID: 211678107

Quantum Element Method for Quantum Eigenvalue Problems

@article{Cheng2020QuantumEM,
  title={Quantum Element Method for Quantum Eigenvalue Problems},
  author={Ming-C. Cheng},
  journal={arXiv: Computational Physics},
  year={2020}
}
  • M. Cheng
  • Published 21 February 2020
  • Physics
  • arXiv: Computational Physics
A previously developed quantum reduced-order model is revised and applied, together with the domain decomposition, to develop the quantum element method (QEM), a methodology for fast and accurate simulation of quantum eigenvalue problems. The concept of the QEM is to partition the simulation domain of a quantum eigenvalue problem into smaller subdomains that are referred to as elements. These elements could be the building blocks for quantum structures of interest. Each of the elements is… 
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References

SHOWING 1-10 OF 59 REFERENCES

The Reduced Basis Element Method: Application to a Thermal Fin Problem

This paper focuses on the definition of the reference shapes, and together with theoretical and numerical justifications of the reduced basis element method, it provides a posteriori error analysis tools that allow us to certify the computational results.

An efficient technique to calculate the normalized wave functions in arbitrary one-dimensional quantum well structures

We present a simple yet unified technique to calculate: (i) the eigenenergies and the normalized eigenstates in quantum wells, (ii) the energy broadened spatially varying density-of-states in leaky

Proper orthogonal decomposition‐based reduced basis element thermal modeling of integrated circuits

Various reduced basis element methods are compared for performing transient thermal simulations of integrated circuits. The reduced basis element method is a type of reduced order modeling that takes

Quantum singular-value decomposition of nonsparse low-rank matrices

A method to exponentiate nonsparse indefinite low-rank matrices on a quantum computer that preserves the phase relations between the singular spaces allowing for efficient algorithms that require operating on the entire singular-value decomposition of a matrix.

A method of finite element tearing and interconnecting and its parallel solution algorithm

A novel domain decomposition approach for the parallel finite element solution of equilibrium equations is presented, which exhibits a degree of parallelism that is not limited by the bandwidth of the finite element system of equations.

A Reduced-Basis Element Method

This note proposes to develop and analyze reduced basis methods for simulating hierarchical flow systems, which is of relevance for studying flows in a network of pipes, an example being a set of arteries or veins.

Some Solutions of Extensive Quantum Equations in Biology, Formation of DNA and Neurobiological Entanglement

Based on the extensive quantum theory of biology and NeuroQuantology, the Schrodinger equation with the linear potential may become the Bessel equation. Its solutions are Bessel functions, and may

Proper-Orthogonal-Decomposition Based Thermal Modeling of Semiconductor Structures

A thermal model of a semiconductor structure is developed using a hierarchical function space, rather than physical space. The thermal model is derived using the proper orthogonal decomposition (POD)

Balancing domain decomposition

It is shown that the equilibrium conditions for the singular problems on subdomains lead to a simple and natural construction of a coarse problem in the Neumann–Neumann algorithm.

Parallel solution of contact shape optimization problems based on Total FETI domain decomposition method

It is shown that the TFETI algorithm is even more efficient for the solution of the contact shape optimization problems as it can exploit effectively a specific structure of the auxiliary problems arising in the semi-analytic analysis.
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